JP2016057479A - Imaging device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an imaging device in which when a light emitting part unit moves from a housing location to a light emitting location, the light emitting part unit is not whipped backward.SOLUTION: A light emitting part holder 303 moves between a housing position where the light emitting part holder is housed in a housing part 315a to be formed in a strobo base 315 and a light emitting position protruding from the housing part 315a. An arm member 307 has one end pivotally supported to the light emitting part holder 303 and has other end pivotally supported to the strobo base 315. A first spring 310 urges a light emitting part unit 301 toward the light emitting device relative to the arm member 307. During the movement of the light emitting part holder 303 from the housing position to the light emitting position, a rotation of the light emitting part unit 301 is regulated relative to the arm member 307 against the first spring 310.SELECTED DRAWING: Figure 5

Description

  The present invention relates to an imaging apparatus such as a digital camera having a built-in movable flash light emitting unit.

  A small digital camera with a large lens barrel has a built-in pop-up strobe unit to prevent the so-called “vignetting” where the strobe light is blocked by the tip of the lens barrel and does not reach the subject. There is. In the pop-up strobe unit, a movable member having a strobe light emitting unit moves between a storage position in the camera main unit and a light emitting position protruding from the camera main unit. As a mechanism for moving the movable member from the storage position in the camera body to the light emission position, there is a pop-up mechanism using two rotating shafts, and there is an advantage that the storage space for the movable member can be reduced due to the demand for miniaturization of the camera. There is. Due to the mechanism using the two rotation axes, vignetting can be avoided while suppressing the pop-up amount by moving the strobe light emitting unit toward the subject side in the optical axis direction of the lens barrel in addition to the height direction of the camera.

  The pop-up mechanism using two rotating shafts is configured such that the first rotating shaft for rotating the arm member is supported by the base member, and the second rotating shaft for rotating the light emitting unit is supported by the arm member. It is. During the pop-up operation, the first rotation shaft and the second rotation shaft rotate in the spring biasing direction. The strobe light emitting unit pops up while being squeezed in the spring biasing direction, that is, behind the camera. Therefore, when a cover member or a part exists behind the strobe light emitting unit, the strobe light emitting unit may interfere with the pop-up operation. Alternatively, in order to avoid interference between the strobe light emitting part and the parts, the peripheral shape of the strobe light emitting part needs to be an opening.

  In Patent Document 1, for the purpose of avoiding a collision of the strobe case with the front cover, the strobe case cannot be rotated with respect to the support plate within a predetermined angle range from the middle when the pop-up state is changed to the retracted state. Is disclosed.

JP 2010-15179 A

  However, in the prior art disclosed in Patent Document 1, the strobe light emitting unit is beaten behind the camera in order to restrict the camera from falling forward (to the subject side).

  The regulation of the behavior of the strobe light emitting unit 501 will be described with reference to the mechanism illustrated in FIG. In this example, a link mechanism 502 that restricts the movement of the strobe light emitting unit 501 is provided, and a follower pin 503 connected to the link mechanism 502 moves along the cam unit 504 during pop-up. The follower pin 503 and the cam portion 504 are sliding portions, and a clearance is further provided in case sand or dust is mixed into the cam portion 504.

  In the configuration illustrated in FIG. 8, the movement direction of the follower pin 503 when the strobe light emitting unit 501 is rotated and the notch direction of the cam unit 504 are parallel, particularly at the start of the pop-up operation. For this reason, if the backlash of the strobe light emission unit 501 is large, the behavior of the strobe light emission unit 501 being swung backward during the pop-up cannot be completely regulated. Therefore, an object of the present invention is to provide an imaging device in which the light emitting unit is not squeezed backward when the light emitting unit moves from the storage position to the light emitting position.

  In order to solve the above problems, the present invention provides a light emitting unit that holds a light emitting unit and moves between a storage position stored in a storage unit formed on a base member and a light emitting position protruding from the storage unit. An arm member having one end pivotally supported by the light emitting unit and the other end pivotally supported by the base member; and the light emitting unit at the light emitting position with respect to the arm member. A first urging member that urges toward the light source, and the light emission to the arm member against the urging force of the first urging member when the light emitting unit moves from the storage position to the light emitting position. Restricting means for restricting rotation of the unit.

  ADVANTAGE OF THE INVENTION According to this invention, when a light emission part unit moves from a storage position to a light emission position, the imaging device which a light emission part unit does not bend back can be provided.

It is a perspective view of an imaging device in an embodiment of the present invention. It is a disassembled perspective view of the imaging device in this embodiment. It is a disassembled perspective view of the strobe unit in the present embodiment. It is a side view which shows the accommodation state and movement start state of the light emission part arm unit in this embodiment. It is a figure which shows the movement state of the light emission part arm unit in this embodiment. It is a figure which shows the movement state of the light emission part arm unit in this embodiment. It is a figure which shows the strobe unit in the light emission position in this embodiment. It is a figure explaining the link mechanism for controlling the action of a strobe light emission part.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. A digital camera is illustrated as an imaging apparatus according to the present embodiment. The positional relationship between the respective parts will be described by defining the subject side as the front side.
FIG. 1 is a perspective view when the imaging apparatus 101 is viewed from the front. FIG. 1A shows a state in which the light emitting unit 301 (see FIG. 3) is in the storage position stored in the apparatus main body of the imaging device 101 in the power-off state. FIG. 1B shows a pop-up state in which the light emitting unit 301 is in a light emitting position protruding from the apparatus main body of the imaging device 101 in the power-on state. In FIG. 1C, in the power-off state, the strobe unit 107 is in a light emission position where it protrudes from the main body of the image pickup apparatus 101, and the tilt liquid crystal unit 110 is rotated 180 ° toward the subject with a rotation axis (not shown) as the center. The rotated state is shown.

  A front cover unit 102 and a lens barrel unit 103 are disposed on the front side of the apparatus main body of the imaging apparatus 101. A lens barrier 104 is incorporated in the lens barrel unit 103, and the lens barrier 104 is closed at the storage position. A side cover unit 105 is incorporated in the side surface portion of the imaging device 101. A strobe lever 106 is disposed on the side cover unit 105. A strobe unit 107 having a light emitting unit 301 (see FIG. 3) and a top cover unit 108 as an exterior member are arranged on the upper surface of the imaging apparatus 101. A rear cover unit 109 and a tilt liquid crystal unit 110 are disposed on the back side of the apparatus main body of the imaging apparatus 101.

  The internal structure of the apparatus main body of the imaging apparatus 101 is covered with a front cover unit 102, a side cover unit 105, a top cover unit 108, a rear cover unit 109, a jack cover unit (not shown), and a bottom cover. On the top cover unit 108, a power button 111, a mode dial 112, an exposure dial 113, a zoom lever 114, and a release button 115 are arranged. When the photographer presses the power button 111, the lens barrier 104 is opened, the lens barrel unit 103 is extended forward, and the power-on state (or the photographing enabled state) shown in FIG.

  The strobe unit 107 including the light emitting unit 116 is supported by a shaft (not shown) provided in the device main body of the imaging device 101, and can be rotated around this shaft. When the photographer depresses the strobe lever 106, the strobe unit 107 is rotated so as to expose the light emitting unit 116 to the outside, and a pop-up state is set. A control unit (not shown) of the imaging apparatus 101 determines the brightness of the subject in the pop-up state of the strobe unit 107. When it is determined that the subject is dark, the light emitting unit 116 emits light with a light amount corresponding to the brightness of the subject. However, even when the flash unit 107 is in the light emission position, the photographer can arbitrarily select light emission / non-light emission of the light emitting unit 116. The flash unit 107 in the light emission position can be returned to the storage position by being manually pushed into the apparatus main body by the photographer. In the storage position illustrated in FIG. 1A, the light emitting unit cover 304 (see FIG. 3) is positioned on the same plane as the top cover unit 108.

  As shown in FIG. 1C, the photographer can rotate the tilt liquid crystal unit 110 180 degrees toward the subject. That is, the photographer can confirm the shooting angle of view on the screen 117 of the tilt liquid crystal unit 110 as appropriate when performing so-called self-shooting with the subject as the subject. Even in the state of FIG. 1C, the photographer can operate the strobe lever 106 to bring the strobe unit 107 into a pop-up state, select light emission / non-light emission of the light emitting unit 116, and press the release button 115 to take a picture. is there.

Next, the configuration of the imaging apparatus 101 will be specifically described with reference to FIG. FIG. 2 is an exploded perspective view of the imaging apparatus 101.
The apparatus main body of the imaging apparatus 101 includes a main chassis 201 that is a main structure, and each unit is held in the chassis. The main chassis 201 holds the lens barrel unit 103 by fastening with screws on the front side. The main chassis 201 holds the battery box unit 202. The battery box unit 202 holds the main board 203.

  The main chassis 201 holds a jog dial unit 204, a rear cover unit 109, a tilt liquid crystal unit 110, and a hinge cover 207 on the back side. A jack cover unit 205 is fastened to the jog dial unit 204 with a screw (not shown) on the side surface on the battery box unit 202 side.

  On the upper surface side of the imaging apparatus 101, the main chassis 201 holds the top cover unit 108. Further, on the bottom surface side of the image pickup apparatus 101, the bottom cover 206 is fastened to the main chassis 201 and the battery box unit 202 by screws (not shown). The strobe unit 107 is fastened to the main chassis 201 with a screw (not shown). The main chassis 201 holds the wireless module substrate 208 and the side cover unit 105 on the side surface on the strobe unit 107 side.

FIG. 3 is an exploded perspective view of the strobe unit 107.
The strobe unit 107 has a light emitting unit 301. The light emitting unit 301 includes a light emitting unit 116, a light emitting unit flexible printed board 302, a light emitting unit holder 303, and a light emitting unit cover 304. A light emitting unit flexible printed circuit board (hereinafter referred to as a light emitting unit flexible) 302 is a wiring member that connects the light emitting unit 116 and a circuit board (strobe substrate 316) described later.

  The light emitting unit 116 includes an Xe (xenon) tube, a reflector, a light emitting unit window, and a trigger coil. The light distribution angle is determined by the reflector and the light emitting unit window so that the strobe light is focused on a region to be imaged (hereinafter referred to as a shooting angle of view). That is, the light collection efficiency can be increased by collecting light to the object field within the shooting angle of view by the reflector and the light emitting unit window. The light emitting unit 116 is provided with an Xe tube extending from the light emitting unit 116 and a trigger coil input terminal (not shown) for applying a voltage. The input terminal is connected to the light emitting unit flexible 302 by soldering.

  The light emitting unit holder 303 stores the light emitting unit 116 in the storage unit 303a. An insertion port 303b for pulling out the light emitting unit flexible 302 is formed on the rear side of the storage unit 303a. The light emitting unit 116 is stored in the storage unit 303 a in a state where the light emitting unit flexible 302 is inserted through the insertion port 303 b of the light emitting unit holder 303. By covering the light emitting unit holder 303 containing the light emitting unit 116 with the light emitting unit cover 304 from above, the light emitting unit 116 is casing. The light emitting unit cover 304 is fixed to the light emitting unit holder 303 by fastening screws 305 from the side. Thereby, the assembly of the light emitting unit 301 is completed.

  An arm unit 306 is assembled to the light emitting unit 301. The arm unit 306 includes an arm member 307, an arm cover member 308, and a magnet 309. The arm member 307 is made of a soft magnetic material such as iron. The arm cover member 308 is made of a synthetic resin material that transmits magnetism. The strobe unit 107 is assembled with a link mechanism for regulating the upper and lower light distribution directions of the light emitting unit 301. On the arm member 307, the first link member A307a and the second link member B307b constituting the link mechanism are caulked and held by the link pins 307c, respectively. The follower pin 307d is caulked and held on the side opposite to the side on which the second link member B307b is caulked. That is, the other end of the first link member A307a is pivotally supported by the second link member B307b. The follower pin 307d of the second link member B307b functions as a follower part.

  A pair of bearing portions 303 c are provided on the bottom surface on the rear side of the light emitting unit holder 303. The arm member 307 is rotatably attached to the pair of bearing portions 303c via the first spring 310 and the first rotation shaft 311. That is, one end of the arm member 307 is pivotally supported by the light emitting unit holder 303. A link screw fastening hole 303 d is provided on the bottom surface of one side of the light emitting unit holder 303. The link screw fastening hole 303 d is fastened by a screw screw 312 and a screw fastening part 307 e provided in the first link member A 307 a of the arm member 307. That is, one end of the first link member A307a is pivotally supported by the light emitting unit holder 303 at a portion different from the portion where the arm member 307 is pivotally supported.

  The first spring 310 urges the light emitting unit 301 in a direction in which the light emitting unit 301 protrudes from the apparatus main body of the imaging device 101. That is, the first spring 310 is a first biasing member that biases the light emitting unit holder 303 toward the light emitting position with respect to the arm member 307. The arm cover member 308 that covers the light emitting unit flexible 302 is assembled to the arm member 307 so that the light emitting unit flexible 302 is not exposed when the light emitting unit 301 is in the pop-up state at the light emitting position. The magnet 309 is accommodated in the arm cover member 308 in a state of being positioned with high accuracy and is fixed by an adhesive. Thereafter, the arm cover member 308 is fixed to the arm member 307 with the screws 313, whereby the assembly of the light emitting unit arm unit 314 is completed. That is, the arm cover member 308 is fixed to a surface of the arm member 307 that faces the storage portion 315a when the arm member 307 is stored in the storage portion 315a. A part of the light emitting section flexible 302 is disposed between the magnet 309 held by the arm cover member 308 and the arm member 307. Even when the arm cover member 308 is fixed to the arm member 307, a space necessary for the movement of the light emitting unit flexible 302 is ensured.

  The light emitting unit arm unit 314 is stored in a storage unit 315a formed as a recess on the top of the strobe base 315 as a base member. Insertion openings 315b and 315c are formed on the front surface of the strobe base 315. The insertion openings 315b and 315c are used to route the light emitting unit flexible 302 to the strobe substrate 316 disposed on the rear side of the strobe base 315. The strobe board 316 is a circuit board for light emission control of the light emitting unit 116.

  When the light emitting unit arm unit 314 is stored in the storage unit 315 a of the strobe base 315, the light emitting unit flexible 302 is passed through the insertion port 315 b and the light emitting unit flexible 302 is pulled out to the front surface of the strobe base 315. The arm member 307 is rotatably attached to the pair of bearing portions 315e provided on the strobe base 315 via the second spring 317 and the second rotation shaft 318. That is, the other end of the arm member 307 is pivotally supported by the strobe base 315. At that time, the follower pin (follower portion) 307d provided on the second link member B307b enters the cam groove portion (first cam portion) 315d of the strobe base 315. Thereby, when the strobe unit 107 performs the pop-up operation, the follower pin 307d moves along the cam groove portion 315d, so that the rotation of the light emitting unit 301 during the pop-up operation can be restricted. That is, the first link member A307a, the second link member B307b, and the cam groove portion 315d constitute a second restricting portion that restricts the rotation of the light emitting unit 301.

  The pair of bearing portions 315e are arranged on the upper side in the height direction of the image pickup apparatus 101 and on the front side in the front-rear direction of the image pickup apparatus 101, which is advantageous for vignetting of strobe light. In other words, the pair of bearing portions 315e is disposed directly below the top cover unit 108 constituting the exterior portion. The second spring 317 biases the light emitting unit 301 in a direction in which the light emitting unit 301 protrudes from the apparatus main body of the imaging device 101.

  Thereafter, an operation of bending the light emitting portion flexible 302 by 180 degrees and passing it through the insertion opening 315c is performed. The light emitting unit flex 302 is routed to a strobe board 316 fixed to the rear side of the strobe base 315 and connected to a connector (not shown) disposed on the strobe board 316. By doing in this way, even in the pop-up state where the light emitting unit 301 is at the light emitting position, the portion where the light emitting unit flexible 302 is exposed can be minimized. The light emitting unit flexible 302 can be connected to a strobe substrate 316 disposed on the rear side of the strobe base 315.

  A magnetic sensor 316 a is mounted on the strobe board 316, and this is a magnetic detection unit that detects the magnetism of a magnet (permanent magnet) 309 fixed to the arm cover member 308. The magnetic sensor 316 a outputs a signal according to the distance from the magnet 309, and the output signal is input to the control unit 316 b that controls switching of the light emitting unit unit 301 between the light emitting disabled state / light emitting enabled state. That is, the control unit 316b performs light emission control of the light emitting unit 301 based on the output of the magnetic sensor 316a.

  The strobe base 315 incorporates a strobe engaging member 319 for holding the light emitting unit 301 in a stored state. The strobe engaging member 319 is supported in a slidable state with respect to the strobe base 315. The strobe engaging member 319 has an inclined portion 319 a and is always urged by the spring 320, the strobe engaging holding member 321 and the screw 322. Since the strobe engaging member 319 is biased by the spring 320, the strobe engaging member 319 always engages the engaged portion 303e of the light emitting unit holder 303 when the light emitting unit 301 is stored, and the light emitting unit 301 Is held in the stowed state. The strobe engagement holding member 321 is formed with an urging portion (second urging member) 321a.

  A capacitor 323 is fixed to the lower part 315 g of the strobe base 315 by a double-sided tape 324. A pair of lead wires (+) 325 and a lead wire (−) 326 are soldered to the capacitor 323. These lead wires are soldered and electrically connected to the strobe board 316 at a location not shown. A plurality of ribs 315 h are formed on the front edge of the storage portion 315 a of the strobe base 315.

Next, the operation of the flash unit 107 will be described with reference to FIGS.
FIG. 4A is a side view showing a storage state of the light emitting unit arm unit 314 of the strobe unit 107. FIG. 4B is a side view showing a state in which the arm unit 306 is rotated at an angle of 6 degrees by the urging force of the second spring 317 about the second rotation shaft 318 in the light emitting unit arm unit 314. It is. FIG. 5A is a side view showing a state in which the arm portion 306 is rotated at an angle of 15 degrees by the urging force of the second spring 317 about the second rotation shaft 318 in the light emitting portion arm unit 314. It is. FIG. 5B is a cross-sectional view further showing the strobe base 315 and the top cover unit 108 in the state of FIG. FIG. 6A is a side view showing a state in which the arm portion 306 is rotated at an angle of 40 degrees by the urging force of the second spring 317 around the second rotation shaft 318 in the light emitting portion arm unit 314. It is. FIG. 6B is a side view of the imaging apparatus 101 in the state of FIG. 6A, and is a diagram illustrating a relationship between the light emitting unit arm unit 314 and the tilt liquid crystal unit 110. FIG. 7A is a side view showing a state where the light emitting unit 301 is popped up to the light emitting position, and FIG. 7B is a cross-sectional view. For simplification, portions not necessary for explanation are omitted in each figure.

  In the housed state of the light emitting unit arm unit 314 shown in FIG. 4A, the first rotating shaft 311 and the engaged portion 303e are close to each other. Therefore, the strobe engaging member 319 cannot prevent the first spring 310 from being urged to rotate (refer to the arrow A direction) about the first rotation shaft 311. In this case, a phenomenon that the light emitting unit 301 rotates in the direction of arrow A, so-called “floating”, may occur. Therefore, in order to suppress “floating”, the urging portion 321a of the strobe engagement holding member 321 urges the cam portion (second cam portion) 303f of the light emitting portion holder 303 in the arrow B direction. The arrow B direction is a direction in which the light emitting unit holder 303 rotates around the first rotation shaft 311 and is opposite to the urging direction of the first spring 310 (arrow A direction). That is, the arrow B direction is a direction against the urging force of the first spring 310. Further, the urging position of the urging portion 321a with respect to the cam portion 303f is set to a position as far as possible from the first rotation shaft 311. That is, by biasing the cam portion 303f by the biasing portion 321a at a position as far as possible from the first rotating shaft 311, even if the biasing force of the biasing portion 321a is small, the biasing force of the first spring 310 is smaller. A large rotational moment can be given. Therefore, occurrence of “floating” can be suppressed. A cam portion 303 f provided on the light emitting portion holder 303 and a biasing portion 321 a that biases the cam portion 303 f in the forward direction restrict the rotation of the light emitting portion holder 303 against the biasing force of the first spring 310. A 1st control part is comprised.

  The light emitting unit 301 tries to rotate by receiving the urging force of the urging unit 321a, but the flange 304a which is a part of the light emitting unit cover 304 abuts against the rib 315h of the strobe base 315. The horizontal posture can be maintained in the stored state.

  FIG. 4B shows a state in which the light emitting unit arm unit 314 is rotated 6 degrees in the direction of arrow C by the urging force of the second spring 317 about the second rotation shaft 318. When using the strobe unit 107, the photographer first depresses the strobe lever 106 (see FIG. 1). The arm portion (not shown) of the strobe lever 106 slides on the inclined portion 319a of the strobe engaging member 319, and the strobe engaging member 319 moves in a direction in which the engagement with the engaged portion 303e of the light emitting unit holder 303 is released. Therefore, the engagement with the engaged portion 303e is released. The urging force of the springs 310 and 317 causes the arm unit 306 to rotate about the second rotation shaft 318 (see the arrow C direction), and the light emitting unit 301 includes the first rotation shaft 311 as the center. It is rotated toward the light emitting position by the urging force of one spring 310 (see the arrow A direction). When the light emitting unit 301 and the arm unit 306 rotate, the light emitting unit 301 cannot rotate backward (arrow A direction) by the urging force of the urging unit 321a in the arrow B direction as described above. It is regulated to be. The light emitting unit arm unit 314 rotates in the arrow C direction about the second rotation shaft 318 by the urging force of the second spring 317.

  FIG. 5 shows a state where the light emitting unit holder 303 has moved to an intermediate position between the storage position and the light emitting position. In the state shown in FIG. 5A, as in the state of FIG. 4B, the light emitting unit 301 is rotated backward (arrow A direction) by the biasing force of the biasing part 321a in the arrow B direction. It is regulated to be impossible. The light emitting unit arm unit 314 rotates in the arrow C direction about the second rotation shaft 318 by the urging force of the second spring 317. At this time, as shown in FIG. 5B, when there are parts such as the top cover unit 108 on the rear side, the light emitting unit holder 303 is moved rearward (in the direction of arrow A) by the urging unit 321a. ) Is restricted. Therefore, interference between the light emitting unit holder 303 and the top cover unit 108 can be avoided. Between the state shown in FIG. 4A and the state shown in FIG. 5A, the first restricting portion and the second restricting portion emit light to the arm member 307 against the urging force of the first spring 310. The rotation of the part holder 303 is restricted.

In the state shown in FIG. 6A, the light emitting unit 301 is sufficiently popped up with respect to the urging unit 321a. Therefore, the cam part 303f of the light emitting part holder 303 does not contact the urging part 321a. Further, the light emitting unit holder 303 rotates backward (in the direction of arrow A) about the first rotation shaft 311 by the biasing force of the first spring 310.
The first link member A307a of the arm member 307 operates in conjunction with the operation of the light emitting unit holder 303. The first link member A307a and the second link member B307b are connected to each other by a link pin 307c. The second link member B307b rotates around a link pin 307c formed on the arm member 307. That is, the second link member B307b is attached to the arm member 307 so as to be rotatable. The follower pin 307d that is caulked and held by the second link member B307b moves in the direction of arrow D and contacts the wall surface portion 315i of the cam groove portion 315d of the strobe base 315. Therefore, the light emitting unit 301 that operates in conjunction with the follower pin 307d rotates with little being swung behind the imaging device 101 (in the direction of arrow A). In conjunction with the pop-up operation of the arm portion 306, the follower pin 307d slides on the wall surface portion 315i of the cam groove portion 315d.

  In the present embodiment, the cam groove 315d and the follower pin 307d of the strobe base 315 are provided with a slight clearance so that sand and dust do not enter and become clogged. That is, the cam groove portion 315d is wider than the diameter of the follower pin 307d. Therefore, there is a possibility that the light emitting unit 301 is rotated while being pinched backward (in the direction of arrow A) of the imaging device 101 around the first rotation shaft 311 by the clearance. However, as shown in FIG. 6B, after the light emitting unit arm unit 314 has sufficiently popped up upward and forward, the cam groove 315d and the follower pin 307d (second restricting unit) are the first time of the light emitting unit 301. The rotation in the direction of arrow A around the moving shaft 311 is mainly restricted. Even if the light emitting unit 301 rotates about the first rotation shaft 311 so as to be squeezed backward (in the direction of arrow A) by the biasing force of the first spring 310, the tilt liquid crystal unit 110 existing at the rear, etc. There is no contact with any parts.

  FIG. 7 shows a state where the light emitting unit holder 303 has moved to the light emitting position. As shown in FIG. 7B, when the light emitting unit 301 is popped up to the light emitting position, a part of the arm member 307 comes into contact with the stopper surface portion 315f of the strobe base 315. Thereby, the rotation of the arm portion 306 in the urging direction (arrow C direction) by the second spring 317 is restricted. Further, when a part of the light emitting unit holder 303 comes into contact with the stopper surface part 307e of the arm member 307, the rotation of the light emitting unit holder 303 in the urging direction (arrow A direction) by the first spring 310 is restricted. Thus, the light emitting unit 301 is held at the light emitting position. Between the state shown in FIG. 6 (A) and the state shown in FIG. 7 (A), the second restricting portion rotates the light emitting portion holder 303 with respect to the arm member 307 against the urging force of the first spring 310. Is regulated. At this time, the first restricting portion does not restrict the rotation of the light emitting portion holder 303 with respect to the arm member 307.

According to this embodiment, in the pop-up strobe unit using two rotating shafts, the strobe light emitting unit can perform a pop-up operation with high quality without being swung behind the apparatus main body.
The configuration of the present invention is not limited to that exemplified in the above embodiment, and the material, shape, dimensions, form, number, arrangement location, etc. can be changed as appropriate without departing from the scope of the present invention. is there.

DESCRIPTION OF SYMBOLS 101 Imaging device 116 Light emission part 301 Light emission part unit 303 Light emission part holder 303f Cam part 307 Arm member 310 1st spring (1st biasing member)
311 First rotation shaft 315 Strobe base (base member)
315d Cam groove (cam part)
317 Second spring 318 Second rotation shaft 321 Strobe engagement holding member 321a urging portion (second urging member)

Claims (5)

An imaging apparatus including a light emitting unit that holds a light emitting unit and moves between a storage position stored in a storage unit formed on a base member and a light emitting position protruding from the storage unit,
An arm member having one end pivotally supported by the light emitting unit and the other end pivotally supported by the base member;
A first biasing member that biases the light emitting unit toward the light emitting position with respect to the arm member;
Restriction means for restricting rotation of the light emitting unit with respect to the arm member against the urging force of the first urging member when the light emitting unit moves from the storage position to the light emitting position; An imaging apparatus comprising:   2. The imaging apparatus according to claim 1, wherein the restricting unit includes a second urging member that urges the light emitting unit in a direction opposite to the urging direction of the first urging member. The restricting means includes a first link member and a second link member connected to each other, and a cam portion formed on the base member,
One end of the first link member is pivotally supported by the light emitting unit at a portion different from a portion where the arm member is pivotally supported, and the other end of the first link member is supported by the second link member. It is pivotally supported,
The imaging apparatus according to claim 1, wherein the second link member includes a follower portion that engages with the cam portion and is rotatably attached to the arm member. The restricting means includes a first restricting portion having a second urging member that urges the light emitting unit in a direction opposite to the urging direction of the first urging member;
A first link member and a second link member connected to each other, and a cam portion formed on the base member;
One end of the first link member is pivotally supported by the light emitting unit at a portion different from a portion where the arm member is pivotally supported, and the other end of the first link member is supported by the second link member. It is pivotally supported,
The second link member includes a second restriction portion that is formed with a follower portion that engages with the cam portion and is rotatably attached to the arm member.
While the light emitting unit moves from the storage position to an intermediate position between the storage position and the light emitting position, the first restricting unit and the second restricting unit rotate the light emitting unit with respect to the arm member. Movement is regulated,
2. The rotation of the light emitting unit with respect to the arm member is restricted by the second restricting unit while the light emitting unit moves from the intermediate position to the light emitting position. The imaging device described. The light emitting unit has a light emitting unit cover,
5. The part according to claim 2, wherein when the light emitting unit is located at the storage position, a part of the light emitting unit cover comes into contact with the base member by an urging force of the second urging member. The imaging device described.